Investigation on Viscoelastic Properties of Cortical Surfaces Using Dynamic Mechanical Analysis

IRPN: Science Pub Date : 2017-12-21 DOI:10.2139/ssrn.3101404
Rakesh Kumar, A. Tiwari, P. Sihota, Dharmendra Tripathi, Navin Kumar, A. Ahmad, S. Ambwani
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引用次数: 1

Abstract

In silico models of bone adaptation attempted to simulate loading-induced osteogenesis (i.e. new bone formation) at cortical bone surfaces (periosteal and endocortical). These models, however, fall short in fitting the site-specific new bone formation at cortical envelops especially at endocortical surface. An anticipated reason may be that same mechanical properties were considered for both periosteal and endocortical surfaces, whereas, properties may be different and location-specific at the two surfaces. Site-specific mechanical properties at cortical bone envelops are not investigated well in the literature. This study mainly aims to characterize mechanical properties (especially viscoelastic properties) at periosteal and endocortical surfaces of Wistar rats femora using Dynamic Mechanical Analysis (DMA). Viscoelastic properties such as storage and loss moduli are estimated. Properties are also compared along anterior, posterior, medial, and lateral sites of cortex at both surfaces. Experimental outcomes indicate that periosteal surface has higher stiffness than endocortical surface across all the anatomical locations, in which, medial region had highest stiffness at the two surfaces. These findings may be useful in developing advanced computer models to precisely predict osteogenesis which may help clinicians in providing informed recommendation on biomechanical strategies such as physical exercise to treat site-specific bone loss.
基于动态力学分析的皮质表面粘弹性研究
骨适应的硅模型试图在皮质骨表面(骨膜和皮质内)模拟负载诱导的成骨(即新骨形成)。然而,这些模型在拟合皮质包膜特别是皮质内表面部位特异性新骨形成方面存在不足。一个预期的原因可能是考虑了骨膜和皮质内表面相同的力学特性,然而,这两个表面的特性可能是不同的和特定位置的。骨皮质包膜的部位特异性力学性能在文献中没有得到很好的研究。本研究主要是利用动态力学分析(Dynamic mechanical Analysis, DMA)对Wistar大鼠股骨骨膜和皮质内表面的力学特性(尤其是粘弹性)进行表征。粘弹性性能,如储存和损失模量的估计。还比较了两个表面皮层的前、后、内、外侧部位的特性。实验结果表明,骨膜表面在所有解剖位置都比皮质内表面具有更高的刚度,其中内侧区域在两个表面具有最高的刚度。这些发现可能有助于开发先进的计算机模型来精确预测骨生成,这可能有助于临床医生就生物力学策略(如体育锻炼)提供明智的建议,以治疗特定部位的骨质流失。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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